Analysis of chaos-coherence peculiarities within the chaotic phenomena of fluid at finite temperature

In this distinctive research, I explored the influence of temperature and momentum-dependent coherence and chaos radiations on particles emanated fluid with quantum correlations. The equations are elucidated by using the interferometry technique to prevail in perspicuous aphorism for the coherence-chaotic field. Chaotic parameter examines the coherence through boson femtoscopy within an evolving boson gas model and probes significant parameters within the produced fluid characterization for the potential of harmonics oscillators. The proportion of condensate of identical bosons, densities distribution, and the correlations functions for the expansion of boson gas are investigated. The findings suggest that the particular temperatures in the relativistic smashing possess the hadronic phase and the resulting sources at that phase containing hundreds of analogous boson particles divulge the robustness of quantum coherence. The correlations are delineated to analyze the coherence and source peculiarities with certain temperature ranges, particles number, and particle pairs averaging momentum. At small pair momenta, the finite condensation reduces the correlations in pion interferometry observations and strives for an insignificant effect at high particles pair momenta. As shown in the plots the graphical interpretations of the density distribution, correlations and chaotic profile against assorted apropos parameters have been demonstrated for pertinent physical reasons. The significant results divulged that the density distributions possession enhance at higher coherent emission and lower temperature regimes. Such findings reveal the lucrativeness in the field of engineering applications.

Automated summary

In this research, the influence of temperature and momentum-dependent coherence and chaos radiations on particles emit fluid with quantum correlations was explored. The findings indicate that at specific temperatures, the fluid from relativistic collisions possesses hadronic phase and reveals the robustness of quantum coherence. The analysis of chaotic parameter and correlation functions reveals the variations of coherence and source characteristics with temperature ranges, particles number, and particle pairs averaging momentum.